File system operation and digital rights management (DRM)

ABSTRACT

File system interaction with digital rights management (DRM) is facilitated by enabling one or more file system components to be DRM-aware. These one or more file system components may be part of a computer operating system. An exemplary system implementation includes: one or more processors; and one or more media in operative communication therewith, the media storing one or more file system components that are configured to provide content having DRM controls to a requesting program in either a raw form or a decrypted form in dependence on whether the DRM controls comprise simple DRM content controls or complex DRM content controls. In another exemplary system implementation, the one or more file system components are configured to provide files with simple DRM content controls to requesting applications in a decrypted form and to provide files with complex DRM content controls to requesting applications in an unaltered form.

TECHNICAL FIELD

This disclosure relates in general to digital rights management (DRM)and in particular, by way of example but not limitation, to enabling afile system component to be DRM-aware and to be able to handle at leastsome DRM-controlled content.

BACKGROUND

Computers are utilized in personal, professional, educational and otherareas and fields to perform functions, provide services, and/orfacilitate access to content. Examples of such content include text,audio, images, audiovisual or multimedia material, executables, somecombination thereof, and other content. Creators of much of this contentoften rely on intellectual property protections such as copyright tosecure control and compensation for their works. However, rights holdersalso usually wish to supplement these legal protections with technicalprotections. This is especially true of content that is in a digitalform because digital content can be copied, sold, shared, transferred,viewed, otherwise used, etc. without undergoing any degradation.Consequently, there is no natural technical-based expiration or otherlimitation on digital content once it has been disseminated.

One technique for offering technical protections (i.e., control) overcontent is digital rights management (DRM). DRM can limit, for example,a user's access to content. Such limitations may include, for instance,limiting the number of times content may be experienced, limiting thenumber of transfers of content, limiting the amount of time content maybe experienced, limiting allowable modifications to content, and soforth. DRM may be implemented in any of a myriad of manners; however,any of these myriad of manners are generally intended to providetechnical controls over content.

Computers typically employ application programs in order to provide theaforementioned functions, services, and content access. Theseapplication programs facilitate content viewing, content modifying, andcontent experiencing in general. Traditionally, in order for DRM to beeffective in controlling content use, the application that is attemptingto interact with DRM-controlled content must be DRM-aware and capable ofenforcing DRM controls. This conventional approach to DRM may beeffective for new applications being developed today for a DRM-enabledworld. Unfortunately, there are many legacy applications that arealready present on computers and that have no understanding of orability to interact with DRM-controlled content.

Accordingly, there is a need for schemes and/or techniques to enablelegacy applications to interact with DRM-controlled content.

SUMMARY

File system interaction with digital rights management (DRM) isfacilitated by enabling one or more file system components to beDRM-aware. These one or more file system components may be, for example,part of a computer operating system. An exemplary system implementationfor file operations and DRM includes: one or more processors; and one ormore media in operative communication with the one or more processors,the one or more media storing one or more file system components thatare adapted to execute on the one or more processors and that areconfigured to provide content having DRM controls to a requestingprogram in either a raw form or a decrypted form in dependence onwhether the DRM controls comprise simple DRM content controls or complexDRM content controls.

Another exemplary system implementation for file system operations andDRM includes: one or more processors; and one or more media in operativecommunication with the one or more processors, the one or more mediastoring one or more file system components that are adapted to executeon the one or more processors and that are configured to provide fileswith simple DRM content controls to requesting applications in adecrypted form and to provide files with complex DRM content controls torequesting applications in an unaltered form.

An exemplary electronically-accessible media implementation includeselectronically-executable instructions that, when executed, direct anelectronic apparatus to perform actions including: inspecting one ormore DRM controls from a tag of DRM-controlled content; determining thatthe one or more DRM controls are simple DRM controls; and providing theDRM-controlled content in a decrypted form when the one or more DRMcontrols are determined to be simple DRM controls; wherein the actionsof inspecting, determining, and providing are performed, at leastpartly, by one or more file system components.

Other method, system, media, and arrangement implementations aredescribed herein.

BRIEF DESCRIPTION OF THE DRAWINGS

The same numbers are used throughout the drawings to reference likeand/or corresponding aspects, features, and components.

FIG. 1 illustrates an exemplary general approach to file systemoperation and digital rights management (DRM).

FIG. 2 is a flow diagram that illustrates an exemplary general methodfor file system operation with DRM.

FIG. 3 illustrates another exemplary general approach to file systemoperation and DRM.

FIG. 4 is a flow diagram that illustrates another exemplary generalmethod for file system operation with DRM.

FIG. 5 illustrates an exemplary computing operating environment that iscapable of (wholly or partially) implementing at least one approach,method, and/or process as described herein.

FIG. 6 is a flow diagram that illustrates an exemplary specific processfor enabling a file system component to be DRM-aware during filecreating/opening.

FIG. 7 is a flow diagram that illustrates an exemplary specific processfor enabling a file system component to be DRM-aware during filecreating/saving.

FIG. 8 illustrates an exemplary general approach to client/serveroperating system (OS) interaction and DRM.

FIG. 9 is a flow diagram that illustrates an exemplary general methodfor client/server OS interaction with DRM.

DETAILED DESCRIPTION

FIG. 1 illustrates an exemplary general approach 100 to file systemoperation and digital rights management (DRM). At least one file systemcomponent 102 is in communication with a program 104 and content withDRM control(s) 106. File system component 102, program 104, and contentwith DRM control(s) 106 may be functioning and/or existing within asingle computer or distributed between or among multiple computers. Anexemplary computer operating environment with an optional remotecomputing device aspect is described below with particular reference toFIG. 5.

File system component 102 may be implemented as all or part of a filesystem of an operating system (OS). For example, it may be the entirefile system of the OS or one or more device drivers thereof. It may alsobe realized as a middleware component. Program 104 may be anyapplication, code, software, middleware, etc. that attempts to accesscontent with DRM control(s) 106.

In a described implementation, content with DRM control(s) 106 may beconstrained by one or more DRM controls on the use of the content. Asillustrated, a tag 108 indicates which DRM control or controls areapplied to content 106. Tag 108 may be any sort of tag or tags that maybe associated with content 106. Examples of tag 108 include a fileheader, an alternate stream (such as an “NTFS” alternate stream), anapplication manifest, and so forth.

DRM controls are divided into simple DRM controls 110 and complex DRMcontrols 112. Simple or basic DRM controls 110 include those DRMcontrols that can be enforced by a file system such as file systemcomponent 102. Thus, simple DRM controls 110 include, for example, thosecontrols directed to read, write, and/or modify.

Complex or rich DRM controls 112 include those DRM controls that cannotbe enforced by a file system. Complex DRM controls 112 include, forexample, no forwarding, no printing, allowing “X” reads, allowing playsfor “Y” days, allowing reads without any modifications (e.g., thuspreventing “save as” functions), and so forth. Although eight differentDRM controls are all illustrated in tag 108, any number of these orother possible DRM controls may alternatively be indicated in tag 108.

In operation, program 104 requests access to content with DRM control(s)106. File system component 102 inspects tag 108 to see which DRMcontrol(s) are applicable to content 106. If tag 108 indicates that onlyone or more simple DRM controls 110 constrain the use of content 106,then file system component 102 performs or causes to be performedDRM-related functions. For example, file system component 102 decrypts(e.g., directly decrypts or indirectly causes to be decrypted) contentwith DRM control(s) 106. Additional exemplary DRM-related functions aredescribed below. After decryption of the content of content with DRMcontrol(s) 106, the decrypted content is provided to program 104.

If, on the other hand, tag 108 indicates that one or more complex DRMcontrols 112 constrain the use of content 106, then file systemcomponent 102 provides content with DRM control(s) 106 to the requestingprogram 104 in a raw state with all DRM protections in force (e.g.,still encrypted, etc.).

Using approach 100 to file system operation and DRM enables a number ofpossibilities. For example, legacy applications that are not DRM-awaremay be given access to DRM-controlled content in at least limitedsituations. For instance, an anti-virus program may access and reviewfiles having content with DRM control(s) 106 even when the anti-virusprogram cannot understand or does not wish to handle DRM controls oncontent. As another instance, DRM controls can be used with legacyapplications that have no innate understanding of DRM functionality toestablish a group or groups that are permitted to access content withsuch legacy applications when the DRM control(s) on such content aresimple DRM controls 110.

FIG. 2 is a flow diagram 200 that illustrates an exemplary generalmethod for file system operation with DRM. Flow diagram 200 includesthree (3) blocks 202, 204, and 206. Actions for these blocks 202, 204,and 206 may be performed, for example, by a file system component 102(of FIG. 1). At block 202, a tag of DRM-controlled content is inspected.For example, the file system component 102 may inspect a tag 108 ofcontent with DRM control(s) 106. At block 204, it is determined that DRMcontrol(s) as indicated in the tag of the DRM-controlled content aresimple. For example, it may be determined from the tag 108 of thecontent with DRM control(s) 106 that any DRM controls thereon are simpleDRM controls 110. At block 206, the content of the DRM-controlledcontent is provided to a requesting program in a decrypted form. Forexample, the content 106 is provided in a decrypted form to a program104.

FIG. 3 illustrates another exemplary general approach 300 to file systemoperation and DRM. As illustrated, approach 300 includes a user computer302 and a license server 304. A user and/or a program of user computer302 desires to access DRM-controlled content, and license server 304 hasthe ability to facilitate the performance of DRM functions withreference to the desired DRM-controlled content.

In a described implementation, a non-DRM-aware application 104(A) and aDRM-aware application 104(B) access one or more files 306 through filesystem component 102. Files 306 include multiple files 306(1), 306(2) .. . 306(n). File 306(1) comprises content that is associated with simpleDRM content controls 110. File 306(2) comprises content that isassociated with complex DRM content controls 112. Simple DRM contentcontrols 110 and complex DRM content controls 112 may be indicatedrespectively for files 306(1) and 306(2) at, for example, a tag of thefile and/or the content thereof.

An application such as DRM-aware application 104(B) may be consideredDRM-aware when it is capable of understanding and enforcing DRM controlsof and on content and the files that include such content. Hence, in theabstract, DRM-aware application 104(B) is capable of accessing files306(1) and 306(2) and interacting with a DRM client 308 so as tofacilitate use of both file 306(1) and file 306(2) to the extentpermitted by simple DRM content controls 110 and complex DRM contentcontrols 112, respectively. Non-DRM-aware application 104(A), on theother hand, is not capable of interacting with DRM client 308 and isthus unable to access or use file 306(1) or file 306(2) absentintervention and aid by file system component 102.

In a described implementation, file system component 102 is capable ofunderstanding and enforcing DRM controls of and on content and the filesthat include such content. Hence, file system component 102 is capableof interacting with DRM client 308 so as to facilitate use of certainfiles 306 that include DRM-controlled content. In this sense, filesystem component 102 is DRM-aware. For example, file system component102 may have a manifest or other type of tag that delineates to DRMclient 308 what or which DRM-controlled content file system component102 is permitted to access. However, file system component 102 isauthorized from a DRM perspective to directly handle those files 306that include simple DRM content controls 110.

Operation of file system component 102, along with certain otherillustrated elements of approach 300, is described in four (4)permutations in which each of non-DRM-aware application 104(A) andDRM-aware application 104(B) each attempt to access file 306(1) and file306(2). In a first of the four described permutations, non-DRM-awareapplication 104(A) attempts to access file 306(1) with simple DRMcontent controls 110. When file system component 102 receives a requestfor file 306(1), file system component 102 detects that file 306(1) isprotected with DRM content controls.

Specifically, file system component 102 detects that file 306(1) isprotected with simple DRM content controls 110. Because the contentcontrols are simple DRM controls 110, file system component 102 acts onbehalf of non-DRM-aware application 104(A) by interacting with DRMclient 308. File system component 102 provides an identity or user toDRM client 308. This identity or user may be representative of the humanuser of user computer 302 and/or the requesting application. Thus, thisidentity may establish or define a user context for DRM.

DRM client 308 uses communication link 310 to contact license server304. Communication link 310 may be a wireless or wireline link, a publicor private network link, a local or wide area network link, somecombination thereof, and so forth. Furthermore, communication link 310may be established using one or more of application protocol(s), remoteprocedure calls (RPCs), simple object access protocol (SOAP) messages,and so forth. Additional examples of communications between twocomputers are described below with particular reference to FIG. 5.

Specifically, DRM client 308 contacts authorization provider component312 via communication link 310. DRM client 308 forwards the identity toauthorization provider 312, which has access to licensing rightsinformation 314. Authorization provider 312 utilizes the forwardedidentity context to reference information related thereto that islocated in licensing rights information 314.

Authorization provider 312 informs DRM client 308 as to what rights havebeen granted to the identity. If the identity has rights to theDRM-controlled content of file 306(1), DRM client 308 uses theappropriate key in accordance with DRM protocols to decrypt the content.File system component 102 may then provide the decrypted content of file306(1) to non-DRM-aware application 104(A). Any DRM controls of simpleDRM content controls 110 for file 306(1) are enforceable by file systemcomponent 102 as non-DRM-aware application 104(A) uses file 306(1).

In a second of the four described permutations, non-DRM-awareapplication 104(A) attempts to access file 306(2) with complex DRMcontent controls 112. When file system component 102 receives a requestfor file 306(2), file system component 102 detects that file 306(2) isprotected with DRM content controls. Specifically, file system component102 detects that file 306(2) is protected with complex DRM contentcontrols 112. Because the content controls are complex DRM controls 112,file system component 102 does not act on behalf of non-DRM-awareapplication 104(A).

In other words, file system component 102 does not interact with DRMclient 308 if the requested file has complex DRM content controls 112.Instead, file system component 102 provides file 306(2) to non-DRM-awareapplication 104(A) in an unaltered form. Because file 306(2) isencrypted in accordance with DRM protocols and non-DRM-aware application104(A) is not able to handle files with DRM controls, non-DRM-awareapplication 104(A) is unable to access file 306(2) and the DRM-relatedprotections for file 306(2) are enforced as intended. Alternatively, asdescribed further below with particular reference to FIG. 6/Element 626,file system component 102 may only provide file 306(2) to applicationsthat are validated as being properly DRM-aware.

In a third of the four described permutations, DRM-aware application104(B) attempts to access file 306(1) with simple DRM content controls110. When file system component 102 receives a request for file 306(1),file system component 102 detects that file 306(1) is protected with DRMcontent controls. Specifically, file system component 102 detects thatfile 306(1) is protected with simple DRM content controls 110. Becausethe content controls are simple DRM controls 110, file system component102 acts on behalf of DRM-aware application 104(B) by interacting withDRM client 308.

As described above with respect to the first permutation, DRM client 308eventually decrypts the content of file 306(1) for file system component102, assuming that the current/user identity context for DRM-awareapplication 104(B) as provided to DRM client 308 has the appropriateDRM-related access rights. File system component 102 may then providethe decrypted content of file 306(1) to DRM-aware application 104(B).Any DRM controls of simple DRM content controls 110 for file 306(1) areenforceable by file system component 102 as DRM-aware application 104(B)uses file 306(1).

In an alternative implementation, file system component 102 may forwardfiles with any DRM content controls 110 and/or 112 to DRM-awareapplication 104(B) in an unaltered form. This permits DRM-awareapplication 104(B) to access such files and enforce any DRM controlswithout direct intervention by file system component 102. File systemcomponent 102 may, in such cases, perform a check to determine whetheran application 104 is a DRM-aware application 104(B), either as a matterof course or in response to an assertion by an application 104 that itis DRM-aware. This check may be accomplished using, for example, digitalsignatures of applications, manifests of applications, and so forth.

In a fourth of the four described permutations, DRM-aware application104(B) attempts to access file 306(2) with complex DRM content controls112. When file system component 102 receives a request for file 306(2),file system component 102 detects that file 306(2) is protected with DRMcontent controls. Specifically, file system component 102 detects thatfile 306(2) is protected with complex DRM content controls 112. Becausethe content controls are complex DRM controls 112, file system component102 does not act on behalf of DRM-aware application 104(B).

In other words, file system component 102 does not interact with DRMclient 308 if the requested file has complex DRM content controls 112.Instead, file system component 102 provides file 306(2) to DRM-awareapplication 104(B) in an unaltered form. This provisioning may beaccomplished by giving a pointer, a handle, etc. for file 306(2) toDRM-aware application 104(B). Although file 306(2) is encrypted inaccordance with DRM protocols, DRM-aware application 104(B) is able tohandle files with DRM controls. Consequently, DRM-aware application104(B) interacts with DRM client 308 (without needing to make anyadditional calls to file system component 102).

This interaction may result in the verification of identity and anyaccompanying DRM rights, the validation of DRM-aware application 104(B),the decryption of the content of file 306(2), and so forth, as describedabove with respect to the first permutation. DRM-aware application104(B) is thus provided with a decrypted version of the DRM-controlledcontent of file 306(2). The DRM-related protections for file 306(2), asenumerated in complex DRM content controls 112, are enforced by the DRMprovisions of DRM-aware application 104(B).

Hence, file system component 102 may provide access to files 306 havingcontent with simple DRM content controls 110 to any type of application.Such simple DRM protections are enforced by file system component 102.For files 306 having content with complex DRM content controls 112, filesystem component 102 provides these files to requesting applications inraw, unaltered form. Consequently, only appropriately DRM-awareapplications 104(B) can access and otherwise use files 306 havingcontent with complex DRM content controls 112.

FIG. 4 is a flow diagram 400 that illustrates another exemplary generalmethod for file system operation with DRM. Flow diagram 400 includesseven (7) blocks 402-414. Actions for these blocks 402-414 may beperformed, for example, by a user computer 302 (of FIG. 3). At block402, an application requests a file. For example, a non-DRM-awareapplication 104(A) or a DRM-aware application 104(B) may request a file306 from a file system component 102.

At block 404, it is determined whether the requested file is protected.For example, the file system component 102 may review the file 306 tosee if it is encrypted, such as when the file 306 is protected with DRM.If the file is not protected, then the requested file is providedunaltered to the requesting application at block 406. For example, thefile system component 102 may pass a handle to the unaltered file 306 tothe requesting application 104(A,B). Regardless of whether therequesting application 104 is a non-DRM-aware application 104(A) or aDRM-aware application 104(B), the requesting application 104(A,B) mayaccess the unaltered and unprotected file 306.

If, on the other hand, the requested file is determined to be protected(at block 404), then it is determined whether the requested file isprotected with simple DRM control(s) at block 408. For example, the filesystem component 102 may inspect a tag of file 306(1,2) to determinewhether it is protected with simple DRM content controls 110. If therequested file is not protected with simple DRM control(s), then therequested file is provided unaltered to the requesting application atblock 406. In this case, if the requesting application 104(A,B) is anon-DRM-aware application 104(A), then the DRM-protected file 306(2)with complex DRM content controls 112 will not be accessed. If therequesting application 104(A,B) is- a DRM-aware application 104(B), thenthe DRM-protected file 306(2) may be accessed, depending on the resultof a DRM analysis effectuated by interaction between the DRM-awareapplication 104(B) and a DRM client 308.

If, on the other hand, the requested file is determined to be protectedwith simple DRM control(s) (at block 408), then a license for theDRM-controlled file verified at block 410. For example, the file systemcomponent 102 interacts with the DRM client 308 in order to have theidentity context verified with a license server 304 at least with regardto the requested file 306(1) with the simple DRM content controls 110.At block 412, the DRM-controlled file is decrypted. For example, the DRMclient 308 uses a key, which is acquired and/or authorized throughexchanges over a communication link 310 with an authorization provider312, to decrypt the requested file 306(1).

At block 414, the requested file in a decrypted form is provided to therequesting application. For example, the file system component 102 maypass a handle to the decrypted file 306(1) to the requesting application104(A,B). Regardless of whether the requesting application 104(A,B) is anon-DRM-aware application 104(A) or a DRM-aware application 104(B), therequesting application 104(A,B) may access the decrypted file 306(1).The file system component 102 may enforce the simple DRM contentcontrol(s) 110 of the decrypted file 306(1).

FIG. 5 illustrates an exemplary computing operating environment 500 thatis capable of (fully or partially) implementing at least one approach,method, and/or process for enabling file system operation with DRM asdescribed herein. Computing environment 500 may be utilized in thecomputer and network architectures described below.

Exemplary computing operating environment 500 is only one example of acomputing environment and is not intended to suggest any limitation asto the scope of use or functionality of the applicable computer(including general electronic device) and network architectures. Neithershould computing environment 500 be interpreted as having any dependencyor requirement relating to any one or any combination of components asillustrated in FIG. 5.

Additionally, file system operation with DRM may be implemented withnumerous other general purpose or special purpose computing systemenvironments or configurations. Examples of well known computingsystems, environments, and/or configurations that may be suitable foruse include, but are not limited to, personal computers, servercomputers, thin clients, thick clients, personal digital assistants(PDAs) or mobile telephones, hand-held or laptop devices, multiprocessorsystems, microprocessor-based systems, set top boxes, programmableconsumer electronics, video game machines, network PCs, minicomputers,mainframe computers, distributed computing environments that include anyof the above systems or devices, and so forth.

Implementations with file system component(s) interacting with DRMfunctionality may be described in the general context ofelectronically-executable instructions. Generally,electronically-executable instructions include routines, programs,objects, components, data structures, etc. that perform particular tasksor implement particular abstract data types.

DRM-aware file system component(s), as described in certainimplementations herein, may also be practiced in distributed computingenvironments where tasks are performed by remotely-linked processingdevices that are connected through a communications network. Especiallyin a distributed computing environment, electronically-executableinstructions may be located in separate storage media, executed bydifferent processors, and/or propagated over transmission media. Forexample, file system commands may be called over a network and executedon a remote computing device that is not directly attached to a computerin which an application is running and attempting to accessDRM-protected content.

Computing environment 500 includes a general-purpose computing device inthe form of a computer 502, which may comprise any electronic devicewith computing and/or processing capabilities. The components ofcomputer 502 may include, but are not limited to, one or more processorsor processing units 504, a system memory 506, and a system bus 508 thatcouples various system components including processor 504 to systemmemory 506.

System bus 508 represents one or more of any of several types of busstructures, including a memory bus or memory controller, a peripheralbus, an accelerated graphics port, and a processor or local bus usingany of a variety of bus architectures. By way of example, sucharchitectures may include an Industry Standard Architecture (ISA) bus, aMicro Channel Architecture (MCA) bus, an Enhanced ISA (EISA) bus, aVideo Electronics Standards Association (VESA) local bus, and aPeripheral Component Interconnects (PCI) bus also known as a Mezzaninebus.

Computer 502 typically includes a variety of electronically-accessiblemedia. Such media may be any available media that is accessible bycomputer 502 or another electronic device, and it includes both volatileand non-volatile media, removable and non-removable media, and storageand transmission media.

System memory 506 includes electronically-accessible media in the formof volatile memory, such as random access memory (RAM) 510, and/ornon-volatile memory, such as read only memory (ROM) 512. A basicinput/output system (BIOS) 514, containing the basic routines that helpto transfer information between elements within computer 502, such asduring start-up, is stored in ROM 512. RAM 510 typically contains dataand/or program modules/instructions that are immediately accessible toand/or being presently operated on by processing unit 504.

Computer 502 may also include other removable/non-removable and/orvolatile/non-volatile electronic storage media. By way of example, FIG.5 illustrates a hard disk drive 516 for reading from and writing to a(typically) non-removable, non-volatile magnetic media (not separatelyshown); a magnetic disk drive 518 for reading from and writing to a(typically) removable, non-volatile magnetic disk 520 (e.g., a “floppydisk”); and an optical disk drive 522 for reading from and/or writing toa (typically) removable, non-volatile optical disk 524 such as a CD-ROM,DVD-ROM, or other optical media. Hard disk drive 516, magnetic diskdrive 518, and optical disk drive 522 are each connected to system bus508 by one or more data media interfaces 526. Alternatively, hard diskdrive 516, magnetic disk drive 518, and optical disk drive 522 may beconnected to system bus 508 by one or more other separate or combinedinterfaces (not shown).

The disk drives and their associated electronically-accessible mediaprovide non-volatile storage of electronically-executable instructions,such as data structures, program modules, and other data for computer502. Although exemplary computer 502 illustrates a hard disk 516, aremovable magnetic disk 520, and a removable optical disk 524, it is tobe appreciated that other types of electronically-accessible media maystore instructions that are accessible by an electronic device, such asmagnetic cassettes or other magnetic storage devices, flash memorycards, CD-ROM, digital versatile disks (DVD) or other optical storage,random access memories (RAM), read only memories (ROM), electricallyerasable programmable read-only memories (EEPROM), and so forth. Inother words, any electronically-accessible media may be utilized torealize the storage media of the exemplary computing system andenvironment 500.

Any number of program modules (or other units or sets of instructions)may be stored on hard disk 516, magnetic disk 520, optical disk 524, ROM512, and/or RAM 510, including by way of example, an operating system527, one or more application programs 528, other program modules 530,and program data 532. By way of example only, operating system 527 maycomprise file system component 102, application programs 528 maycomprise program and/or applications 104, and program data 532 maycomprise files 306 and/or the content 106 thereof. DRM client 308 mayalso optionally comprise part of operating system 527. If so, DRM client308 may exist as part of operating system 527 at the time of originalmanufacture, or it may be subsequently installed on top of operatingsystem 527, and so forth. Alternatively, DRM client 308 may be amiddleware component of computer 502 and/or user computer 302 (of FIG.3).

A user may enter commands and information into computer 502 via inputdevices such as a keyboard 534 and a pointing device 536 (e.g., a“mouse”). Other input devices 538 (not shown specifically) may include amicrophone, joystick, game pad, satellite dish, serial port, scanner,and/or the like. These and other input devices are connected toprocessing unit 504 via input/output interfaces 540 that are coupled tosystem bus 508. However, they may instead be connected by otherinterface and bus structures, such as a parallel port, a game port, auniversal serial bus (USB) port, an IEEE 1394 interface, an IEEE 802.11interface, and so forth.

A monitor 542 or other type of display device may also be connected tosystem bus 508 via an interface, such as a video adapter 544. Inaddition to monitor 542, other output peripheral devices may includecomponents such as speakers (not shown) and a printer 546, which may beconnected to computer 502 via input/output interfaces 540.

Computer 502 may operate in a networked environment using logicalconnections to one or more remote computers, such as a remote computingdevice 548. By way of example, remote computing device 548 may be apersonal computer, a portable computer (e.g., laptop computer, tabletcomputer, PDA, mobile station, etc.), a server, a router, a networkcomputer, a peer device, other common network node, or other computertype as listed above, and so forth. Remote computing device 548 isillustrated as a portable computer that may include many or all of theelements and features described herein relative to computer 502.

Logical connections between computer 502 and remote computer 548 aredepicted as a local area network (LAN) 550 and a general wide areanetwork (WAN) 552. Such networking environments are commonplace inoffices, enterprise-wide computer networks, intranets, the Internet,fixed and mobile telephone networks, other wireless networks, and soforth.

When implemented in a LAN networking environment, computer 502 isconnected to a local area network 550 via a network interface or adapter554. When implemented in a WAN networking environment, computer 502typically includes a modem 556 or other means for establishingcommunications over wide area network 552. Modem 556, which may beinternal or external to computer 502, may be connected to system bus 508via input/output interfaces 540 or any other appropriate mechanism(s).It is to be appreciated that the illustrated network connections areexemplary and that other means of establishing communication link(s)between computers 502 and 548 may be employed.

In a networked environment, such as that illustrated with computingenvironment 500, program modules or other instructions that are depictedrelative to computer 502, or portions thereof, may be fully or partiallystored in a remote memory storage device. By way of example, remoteapplication programs 558 reside on a memory device of remote computer548. Also, for purposes of illustration, application programs 528 andother executable instructions such as operating system 527 areillustrated herein as discrete blocks, but it is recognized that suchprograms, components, and other instructions reside at various times indifferent storage components of computing device 502 (and/or remotecomputing device 548) and are executed by data processor(s) 504 ofcomputer 502 (and/or those of remote computing device 548).

The methods and processes of FIGS. 2, 4, 6, 7, and 9 are illustrated inflow diagrams that are divided into multiple blocks. However, the orderin which the methods and processes are described is not intended to beconstrued as a limitation, and any number of the described blocks can becombined in any order to implement one or more methods or processes forfile system operation and DRM. Furthermore, although the methods andprocesses are described herein with reference to the variousimplementations or approaches of FIGS. 1, 3, and 8 (as well as theexemplary system environment of FIG. 5) where applicable, the methodsand processes can be implemented in any suitable hardware, software,firmware, or combination thereof and using any suitable networkarchitectures, file system configurations, DRM technologies, and soforth.

FIG. 6 is a flow diagram 600 that illustrates an exemplary specificprocess for enabling a file system component 102 to be DRM-aware duringfile creating/opening. The exemplary specific process of flow diagram600 is divided into a user mode portion 602 and a kernel mode portion604. In user mode portion 602, an application #1 104(1) is creating afile, such as a file 306 (of FIG. 3). Also, an application #2 104(2) isopening a file, such as a file 306. These create file and open fileoperations instigate interaction with a file system, such as one or morefile system components 102. The remainder of the process of flow diagram600 occurs within kernel mode portion 604.

In kernel mode portion 604 at block 606, a file system “NTFS” receivesthese operational requests. “NTFS” is an acronym for the New TechnologyFile System of a Microsoft® Windows® operating system such as WindowsXP. NTFS initiates a callout to “EFS” to determine whether the file tobe created or opened is to be protected or is already protected,respectively, at block 608. “EFS” is an acronym for Encrypting FileSystem, which is also present in certain Microsoft® Windows® operatingsystems such as Windows XP. Although the described implementation refersspecifically to NTFS and EFS, alternative operating systems and/oroperating system components may be employed for any of the describedmethods, approaches, and processes. For example, any file system with afile folder encryption component, driver, and/or functionality may beused.

NTFS may alternatively only initiate a callout to EFS (at block 608) ifNTFS cannot directly manipulate (e.g., open) the relevant file. However,in a described implementation at block 610, EFS determines whether thefile is protected. If the file is not protected, then control isreturned to NTFS (via EFS block 608) with no action being taken by EFS.If the file is protected (as determined at block 610), EFS examines thefile data at block 612 to determine the type of protection. If theprotection is a standard encryption or other non-DRM protection, thenEFS decrypts the file and the decrypted file is returned to NTFS (viaEFS block 608).

If, on the other hand, the examination of the file data (at block 612)indicates a DRM type protection, then it is determined at block 614whether the DRM protection is complex. If the DRM content controls arenot complex, then a callout to a DRM module or other functionality isinitiated at block 616. Because the DRM content controls are notcomplex, EFS and NTFS can enforce the DRM content controls. However, theDRM functionality still determines whether the user has access rights tothe file at block 618. The user is usually the human user, but it mayoptionally be the requesting application 104 from user mode portion 602.If the user does not have access rights, the event is logged in anapplication (or security) log for security purposes at block 620, andprocess 600 may terminate, optionally after returning some type of errorcode or status to the requesting application 104.

If, on the other hand, the user is determined to have access rights (atblock 618), then the user license is retrieved at block 622. In order toretrieve the user license and/or verify user access rights, groupmembership (or other authorization data) may be checked at block 624 (asindicated by connection “A”). After the user license is retrieved (atblock 622), the content of the file is decrypted. After contentdecryption and file opening, process 600 may terminate.

Returning to block 614, if the DRM content controls are determined to becomplex, then the requesting application 104 is validated from a DRMperspective at block 626. In other words, whether the requestingapplication 104 is a trusted DRM application that has been appropriatelysigned is validated. The requesting application 104 may be validated asa trusted DRM application, for example, by referring to its manifest,which lists and/or defines the binaries associated with an applicationand is frequently digitally signed.

Although block 626 is an optional block, performing these action(s) atthe file system level may limit or even prevent some brute force attackson the DRM functionality. If the validation fails, then EFS/NTFS deniesto the calling application 104 access to the file. If the validationsucceeds, the content (unaltered) is returned to the calling application104. Hence, the validated and DRM-aware calling application 104 mayinteract with the DRM functionality and enforce the complex DRMcontrols. Regardless of whether the requesting application 104 isvalidated, process 600 may terminate thereafter.

FIG. 7 is a flow diagram 700 that illustrates an exemplary specificprocess for enabling a file system component 102 to be DRM-aware duringfile creating/saving. Generally, applications that are not DRM-aware orthat are not aware that particular content is or is to be protected callthe standard file system (e.g., NTFS in FIGS. 6 and 7) ApplicationProgramming Interfaces (APIs) to save the file, append to the file,modify a block of the file content, and so forth. The file systemperforms a callout to an abstraction layer (e.g., an EFS module, part,driver, etc. in FIGS. 6 and 7) to examine the content and determine ifit contains one or more tags that indicate that it is or should beprotected by the DRM functionality. If the content is tagged with DRMattributes for DRM content controls, the abstraction layer acts onbehalf of the application to call the DRM client APIs to obtain alicense, encrypt the content, and so forth.

Specifically, the exemplary process of flow diagram 700 is divided intouser mode portion 602 and kernel mode portion 604. In user mode portion602, application #1 104(1) is creating a file, and application #2 104(2)is saving/modifying a file, such as a file 306 (of FIG. 3). Saving inthe abstract can refer to creating and then writing a file, opening orreading an existing file and then writing changes thereto, and so forth.These create file and save file operations instigate interaction with afile system, such as one or more file system components 102. Theremainder of the process of flow diagram 700 occurs within kernel modeportion 604.

In kernel mode portion 604 at block 606, a file system component NTFSreceives these operational requests. NTFS initiates a callout to EFS todetermine whether the file to be created or saved/modified is to beprotected or is already protected, respectively, at block 608. NTFS mayalternatively only initiate a callout to EFS (from block 606 to block608) if NTFS knows that the relevant file is to be encrypted inaccordance with some scheme, which may or may not be related to DRM.

Regardless, in this described implementation at block 702, EFSdetermines whether there is a DRM attribute for the file. If there is noDRM attribute associated with the file, then control is returned to EFS.One of at least two options may occur at EFS (at block 608). First, ifother (non-DRM) encryption protection is appropriate, EFS may effectuatesuch encryption before returning control to NTFS. Second, if noencryption is appropriate, EFS returns control to NTFS without anyencryption action being taken by EFS. If, on the other hand, there is aDRM attribute associated with the file (as determined at block 702), acallout to a DRM client API( ) is performed to activate the DRMfunctionality at block 704.

At block 618′, the DRM client determines whether the current usercontext has access rights to the file, and, if so, whether such rightsinclude saving/modifying the DRM-controlled content. If the current usercontext does not include saving/modifying access rights, then theattempted manipulation of DRM-controlled content fails and the event islogged in an application (or security) log at block 620. Thereafter,control is returned to NTFS (at block 606). If, on the other hand, thecurrent user context does include saving/modifying access rights (asdetermined at block 618′), then a user license is retrieved at block622.

When a user license is successfully retrieved (at block 622), theDRM-controlled content is encrypted by the DRM client (of block 704).Also, the DRM-controlled content may be returned to the callingapplication via EFS (of block 608) and/or NTFS (of block 606). Althoughillustrated separately, NTFS and EFS may have no logical or actualdivision within a file system component or components.

File system operation with DRM may provide a number of possibilities.For example, as described in certain general implementations herein, afile system can abstract and provide a DRM functionality layer toapplications that cannot provide DRM content enforcement or are notaware of DRM client APIs on the platform. DRM client subsystems rely onthe application being trusted (e.g., digitally signed with anappropriate code) and DRM-aware. By moving the abstraction layer lower(e.g., into the file system), EFS or another encrypting file systemcomponent may be considered to be a trusted DRM-aware application. Forexample, enabling the file system to be DRM-aware allows for ananti-virus program to scan and verify content as being virus-free whenthat content is DRM protected even if the anti-virus scanner is notDRM-aware.

A file system can also provide a group encryption model for files,applications, and users by combining a file system driver with a DRMclient subsystem. Users that have applications that need basic sharingof encrypted content among user groups can obtain seamless group sharingof content through DRM functionality such as a DRM client/serverlicensing architecture. The DRM client determines access andencrypts/decrypts content based on the license server permissions.Neither the upper-level file system, nor the application, nor the userneed be aware of the DRM capability of the lower-level file systembecause the capability inherently results from using EFS or anotherencrypting file system component as a DRM-enabled application.

A validation component of a file system may provide additionalperformance and security enhancements to a file system operation withDRM scheme. For example, when multiple DRM-aware applications arerunning under the same user context and accessing DRM-protected files,EFS or another encrypting file system component can enhance performanceby maintaining a user context cache to the DRM client for validatingusers and obtaining licenses for DRM-controlled content on behalf ofsuch users. In other words, after a DRM-aware application initiallyretrieves a license for DRM-controlled content, other DRM-awareapplications that are operating in the same or joint user context maybenefit from the cached validation and licensing retrieval.

An encrypting file system component such as EFS can also ensure thateven DRM-aware applications are validated prior to returning protectedcontent. Even if the content is protected with rich DRM controls, theEFS component may refuse to return any content, whether still encryptedor not, to an application that is not trusted as evidenced by thepossession of a valid code signature in the application. This can limitor prevent an un-trusted application from acquiring encrypted contentand then performing brute force attacks thereon. This is also describedfurther above with reference to block 626 of FIG. 6.

FIG. 8 illustrates an exemplary general approach 800 to client/serveroperating system (OS) interaction and DRM. A first user computer 302(1)having a client OS that is not DRM-aware 802(A) and a second usercomputer 302(2) having a client OS that is DRM-aware 802(B) areillustrated. An administrative computer 804 having a server OS 806 isalso illustrated. In this described implementation, server OS 806 isDRM-aware. Although the computer having server OS 806 is illustrated asan administrative computer 804, it may alternatively be any generalserver computer.

Server OS 806 is communicating with non-DRM-aware client OS 802(A) ofuser computer 302(1) via communication link 310(1) and with DRM-awareclient OS 802(B) of user computer 302(2) via communication link 310(2).Server OS 806 interacts with non-DRM-aware client OS 802(A) andDRM-aware client OS 802(B) differently because of their differingDRM-aware statuses.

Specifically, DRM-controlled content is sent from server OS 806 toDRM-aware client OS 802(B) unaltered so that it may handle theDRM-controlled content locally at user computer 302(2). For example,DRM-aware client OS 802(B) may appropriately handle DRM-controlledcontent using a DRM client 308 (of FIG. 3) and/or one or more DRM-awarefile system components 102.

However, with non-DRM-aware client OS 802(A), server OS 806 firsthandles any possible license acquisition and content decryption prior tosending the content to non-DRM-aware client OS 802(A) provided thatserver OS 806 is capable of enforcing the DRM controls. These controlsmay correspond to simple DRM content controls 110 (of FIG. 1). Byproviding decrypted DRM-controlled content to non-DRM-aware client OS802(A), server OS 806 enables legacy, non-DRM-aware client OS 802(A) toaccess/manipulate/use/etc. the DRM-controlled content.

FIG. 9 is a flow diagram 900 that illustrates an exemplary generalmethod for client/server OS interaction with DRM. Flow diagram 900includes four (4) blocks 902-908. Actions for these blocks 902-908 maybe performed, for example, by a server OS 806 (of FIG. 8) in conjunctionwith a non-DRM-aware client OS 802(A) and a DRM-aware client OS 802(B),along with their respective computers 804, 302(1), and 302(2).

At block 902, a server OS interrogates a client OS. For example, theserver OS 806 may interrogate the non-DRM-aware client OS 802(A) and/orthe DRM-aware client OS 802(B). At block 904, the server OS determinesthrough the interrogation (and optionally a verification) whether theclient OS is DRM-aware. For example, the server OS 806 may determinethat the client OS 802(A) is not DRM-aware and that the client OS 802(B)is DRM-aware. Alternatively, this determination may be a result of anaffirmative assertion by the DRM-aware client OS 802(B) (e.g., via a(verifiable) DRM-capable indicator sent from the DRM-aware client OS802(B) to the server OS 806).

If it is determined that the client OS is not DRM-aware (at block 904),then requested content that is DRM-protected is returned to the clientOS in a decrypted form at block 906. For example, the server OS 806 mayreturn content with simple DRM controls in a decrypted form to thenon-DRM-aware client OS 802(A). If, on the other hand, it is determinedthat the client OS is DRM-aware (at block 904), then requested contentthat is DRM-protected is returned to the client OS in an unaltered orraw binary form at block 908. For example, the server OS 806 may returnDRM-controlled content in an unaltered form to the DRM-aware client OS802(B).

Although systems, media, methods, approaches, processes, etc. have beendescribed in language specific to structural and functional featuresand/or methods, it is to be understood that the invention defined in theappended claims is not necessarily limited to the specific features ormethods described. Rather, the specific features and methods aredisclosed as exemplary forms of implementing the claimed invention.

1. One or more electronically-accessible storage media comprisingelectronically-executable instructions that, when executed, direct anelectronic apparatus to perform actions comprising: inspecting, by oneor more file system components, one or more digital rights management(DRM) controls from a tag of DRM-controlled content; determining, by oneor more file system components, if the one or more DRM controls aresimple DRM controls or complex DRM controls; if the one or more DRMcontrols are determined to be simple DRM controls, decrypting, by theone or more file system components, the DRM-controlled content into adecrypted form and providing the decrypted content to an application;and if the one or more DRM controls are determined to be complex DRMcontrols, providing, by the one or more file system components, theDRM-controlled content in an encrypted form to a DRM enabled applicationfor further processing.
 2. The one or more electronically-accessiblestorage media comprising the electronically-executable instructionsthat, when executed, direct an electronic apparatus to perform theactions as recited in claim 1, wherein the simple DRM controls compriseat least one of read, write, or modify.
 3. The one or moreelectronically-accessible storage media comprising theelectronically-executable instructions that, when executed, direct anelectronic apparatus to perform the actions as recited in claim 1,wherein the one or more file system components comprise at least part ofan operating system for a computer.
 4. The one or moreelectronically-accessible storage media comprising theelectronically-executable instructions that, when executed, direct anelectronic apparatus to perform the actions as recited in claim 1,wherein the one or more file system components comprise at least part ofat least one middleware component for a computer.
 5. The one or moreelectronically-accessible storage media comprising theelectronically-executable instructions that, when executed, direct anelectronic apparatus to perform the actions as recited in claim 1,wherein the actions of inspecting, determining, and providing areperformed responsive to an action of receiving a request for theDRM-controlled content from a program.
 6. The one or moreelectronically-accessible storage media comprising theelectronically-executable instructions that, when executed, direct anelectronic apparatus to perform the actions as recited in claim 5,wherein the action of providing comprises the action of providing theDRM-controlled content in the decrypted form or in the encrypted form tothe program.
 7. One or more electronically-accessible storage mediacomprising electronically-executable instructions that, when executed,direct an electronic apparatus to perform actions comprising:determining, by one or more file system components, whether a requestedfile is protected; if the requested file is protected, determining, bythe one or more file system components, whether the requested file isprotected with one or more simple digital rights management (DRM)controls or one or more complex DRM controls; if the requested file isdetermined to be protected with one or more simple DRM controls,decrypting, by the one or more file system components, the requestedfile and providing the decrypted requested file to a requestingapplication; and if the requested file is determined to be protectedwith one or more complex DRM controls, providing, by the one or morefile system components, the requested file unaltered to the requestingapplication; and if the requested file is not protected, providing, bythe one or more file system components, the requested file unaltered tothe requesting application.
 8. The one or more electronically-accessiblestorage media comprising the electronically-executable instructionsthat, when executed, direct an electronic apparatus to perform theactions as recited in claim 7, wherein at least one of the one or morefile system components comprise at least one file system component of anoperating system.
 9. The one or more electronically-accessible storagemedia comprising the electronically-executable instructions that, whenexecuted, direct an electronic apparatus to perform the actions asrecited in claim 7, wherein the action of determining whether arequested file is protected comprises the action of determining whetherthe requested file is protected with at least one DRM content control.10. The one or more electronically-accessible storage media as recitedin claim 7, wherein the electronically-executable instructions, whenexecuted, direct an electronic apparatus to perform, if the requestedfile is determined to be protected with the one or more simple DRMcontrols and prior to the action of decrypting, a further actioncomprising: verifying that a current user context possesses a license toaccess the requested file.
 11. The one or more electronically-accessiblestorage media comprising the electronically-executable instructionsthat, when executed, direct an electronic apparatus to perform theactions as recited in claim 10, wherein the action of verifying isinitiated by at least one DRM client component.
 12. The one or moreelectronically-accessible storage media comprising theelectronically-executable instructions that, when executed, direct anelectronic apparatus to perform the actions as recited in claim 10,wherein the current user context corresponds to at least one of a humanuser and the requesting application.
 13. One or moreelectronically-accessible storage media comprisingelectronically-executable instructions that, when executed, direct anelectronic apparatus to perform actions comprising: providing, by one ormore file system components, content with digital rights management(DRM) content controls to requesting applications in a decrypted formwhen the DRM content controls only comprise one or more of reading,writing, or modifying controls; and providing, by the one or more filesystem components, content with DRM content controls to requestingapplications in an unaltered form when the DRM content controls includeat least one control that does not comprise a reading, a writing, or amodifying control.
 14. The one or more electronically-accessible storagemedia comprising the electronically-executable instructions that, whenexecuted, direct an electronic apparatus to perform the actions asrecited in claim 13, wherein the at least one of the one or more filesystem components comprise at least part of a middleware component. 15.The one or more electronically-accessible storage media comprising theelectronically-executable instructions that, when executed, direct anelectronic apparatus to perform the actions as recited in claim 13,wherein the action of providing content with DRM content controls torequesting applications in an unaltered form comprises the action of:providing the content with DRM content controls to the requestingapplications in the unaltered form only after the requestingapplications have been verified as trusted and DRM-aware.